JP6334641B2 - Air circuit breaker pull-in and pull-out device - Google Patents

Description

  The present invention relates to a draw-in and draw-out device for an air circuit breaker, and more particularly, a disconnected position, a test position, and an input. If an abnormal operation such as over-drawing or over-drawing occurs at the connected position, the breaker body will stop at the set position accurately to prevent damage to the breaker and cradle. The present invention relates to an air circuit breaker drawing and drawing device.

  In general, an air circuit breaker is a type of circuit breaker that cuts off current when a load is opened or closed in a power transmission, substation, or electric circuit, or when an accident such as grounding or short-circuit occurs. Used for.

  The air circuit breaker may be provided with a cradle for inspection, use or replacement of the circuit breaker body. The air circuit breaker equipped with a cradle has a fixed type circuit breaker in which the main body of the circuit breaker is fixed to the cradle, and the main body of the circuit breaker is drawn into or withdrawn from the cradle. There is a draw-out type circuit breaker. Hereinafter, the drawer type circuit breaker will be described.

  When the circuit breaker body is pulled into the cradle for energization of current, the air circuit breaker performs a turn-on (on) and trip (off) operation in the retracted state. If an accident current occurs on the track with the air circuit breaker turned on, the air circuit breaker interrupts the accident current after a predetermined time or immediately depending on the magnitude of the accident current.

  The drawing-in and drawing-out device applied to such an air circuit breaker is a device provided for drawing the breaker body into or out of the cradle. In general, the retractor for the air circuit breaker is equipped with a moving rack provided on the upper surface of the circuit breaker body so that it can be linearly transferred to the inside of the cradle, and a screw connected to the transfer carriage from the handle. It is composed of a screw shaft (or a lead screw) that converts the rotational driving force into a linear moving force and transmits it to the transfer carriage, and when the handle is connected to the screw shaft and rotated, the rotational driving force is linearized by the screw shaft. It is converted into a moving force, and the transfer carriage is moved linearly, whereby the circuit breaker body placed on the upper part is pulled or pulled out.

  FIG. 15 is an internal configuration diagram of a conventional air circuit breaker, FIG. 16 is a plan view of a conventional air circuit breaker retracting and drawing device, and FIG. 17 is a conventional air circuit breaker retracting device. FIG. 5 is a perspective view of a screw shaft and a coupling applied to the drawing device.

  The air circuit breaker 100 according to the prior art mainly includes a movable contact and a stationary contact (not shown) for each phase and an insulating partition that electrically insulates the movable contact and the fixed contact for each phase. The circuit breaker body 101, the cradle 102 that houses the circuit breaker body 101 and connects the power supply side and load side electric circuit of the external power system circuit, and the phase in the circuit breaker body 101 An opening / closing mechanism 103 that supplies a driving force for simultaneously opening and closing the movable contacts, and a girder provided at the lower end of the front surface of the cradle 102 to provide the user with an approach means for operating the air circuit breaker ) 104.

  As shown in FIG. 16 or FIG. 17, the retractor and extractor for the air circuit breaker according to the prior art includes a retract and extract shaft 122, a screw shaft 121, a transfer carriage 120, a coupling 126, springs 127 and 128, and a reset actuator. 124, a display rod (or indicator) 123, and a lock plate 129. Here, the coupling 126 and the springs 127 and 128 constitute a coupling device, and the coupling device has a power transmission possible position where the pulling and pulling driving force by the handle H can be transmitted to the transfer carriage 120 and a power transmission stop position where the coupling cannot be transmitted. And can be moved.

  The reset actuator 124 accumulates elastic energy by the pressure of the user and pressurizes the springs 127 and 128, whereby the coupling 126 is in a position to transmit the rotational driving force from the pull-in and pull-out shaft 122 to the screw shaft 121. To be. The reset actuator 124 is a component that has a tip 124b that extends through the support member 125 and restricts downward movement, a reset pressing end 124a, and a protruding portion (not indicated) protruding on one side. A part of the protrusion is provided with a latch recess 124c in which the latch portion 123b of the display rod 123 is inserted and restrained or released and released.

  The display rod 123 restrains the reset actuator 124 or transfers the latch portion 123b that releases the restraint of the reset actuator 124 each time the circuit breaker body 101 reaches three positions, ie, a breaking position, a test position, and a closing position. A twist portion 123a that is connected to the carriage 120 and rotates by linear movement of the transfer carriage 120 to display the position of the circuit breaker body 101 is provided.

  Arrows are displayed on the end surface of the position display portion 123c of the display rod 123 corresponding to the three positions of the breaker body 101, that is, the break position, the test position, and the closing position. Markings corresponding to the blocking position, the test position, and the loading position are displayed around the position display portion exposure hole 104c.

  The lock plate 129 can restrain (brake) the coupling 126 by coming into contact with the outer peripheral surface of the coupling 126, and each time the display rod 123 releases the reset actuator 124 at three positions of the circuit breaker body 101. By temporarily restraining (braking) the coupling 126, the drawing-in or drawing-out operation of the circuit breaker body 101 is temporarily stopped. More specifically, the lock plate 129 is a plate-like member, and when the rectangular outer peripheral surface portion 126b of the coupling 126 is inserted, the rectangular inner peripheral surface portion 129a can be stopped so that the rotation of the coupling 126 can be stopped. Is provided. Each time the latch portion 123b of the display rod 123 releases the reset actuator 124 at three positions of the circuit breaker body 101, the lock plate 129 is moved downward in FIG. 16 by the restoring force of the upper spring 127, that is, the tensile force. The rotation of the coupling 126 is temporarily stopped by moving and fitting the rectangular outer peripheral surface portion 126b of the coupling 126 to the rectangular inner peripheral surface portion 129a as in the state of FIG.

  Hereinafter, the operation of the pull-in and pull-out device of the air circuit breaker according to the prior art will be described. 18 to 20 are operation state diagrams of the retractor and the pull-out device of the air circuit breaker according to the prior art, and show a power transmission stop state, a power transmission enable state, and a power transmission restraint state by coupling, respectively.

  In the state of FIG. 18, the coupling 126 is in a power transmission stop position where the screw shaft 121 and the pull-in and pull-out shaft 122 are not connected. The springs 127 and 128 are in a state in which elastic energy is released, and the reset actuator 124 is in a position retracted downward.

  In this state, even if the user connects the handle H to the handle connecting portion 122a of the pull-in and pull-out shaft 122 and rotates it, the pull-in and pull-out shaft 122 is only in contact with the end of the screw shaft 121. Since drive connection (connection capable of power transmission) is not performed, the pull-in and pull-out shaft 122 idles, and no rotational force is transmitted to the screw shaft 121. Each time the pull-in and pull-out device of the air circuit breaker reaches the three positions of the break position, the test position, and the closing position, it automatically returns to such an initial state.

  In this state, when the user presses the reset pressing end portion 124a of the reset actuator 124, the spring support portion (not shown) of the reset actuator 124 linearly moves upward as shown in FIG. The spring 127 is compressed to accumulate elastic energy, and the coupling 126 is pressurized and moves upward. Then, the rectangular inner peripheral surface portion 126b-1 of the coupling 126 is fitted and connected to both the square portion 121b of the screw shaft 121 and the square portion 122c of the drawing and drawing shaft 122, so that the screw shaft 121 and the drawing and drawing shaft are connected. The drive connection with 122 is made and ready for driving in the pull-in or pull-out direction.

  As shown in FIG. 19, the coupling 126 completes the drive connection between the screw shaft 121 and the pull-in and pull-out shaft 122 and power transmission is possible, so that the user can pull out (draw out) the breaker body 10. When the handle H is connected to the handle connecting portion 122 a of the pull-in and pull-out shaft 122 and is rotated counterclockwise (clockwise), the counterclockwise (clockwise) rotation of the pull-in and pull-out shaft 122 is driven and connected by the coupling 126. The screw shaft 121 thus rotated is rotated in the counterclockwise (clockwise) direction, whereby the transfer carriage 120 moves upward (downward) together with the screw portion 121a that rotates in the counterclockwise (clockwise) direction. ) The circuit breaker body 101 moves in the retracting (drawing) direction by the movement.

  On the other hand, when the circuit breaker body 101 moves in the drawing (drawing) direction and reaches any one of the closing position, the test position, or the breaking position, the twisted portion 123a of the display rod 123 is rotated by the movement of the transfer carriage 120. When the latch portion 123b of the display rod 123 is disengaged from the latch recess 124c of the reset actuator 124, the reset actuator 124 is released and is locked as shown in FIG. The plate 129 moves downward, and the rectangular outer peripheral surface portion 126b of the coupling 126 is fitted into the rectangular constraining portion 129a of the lock plate 129 to constrain (brake) the coupling 126. Therefore, the screw shaft 121 and the pull-in / draw-out shaft 122 are temporarily stopped to indicate to the user that the circuit breaker body 101 has reached any one of the loading position, the test position, and the blocking position.

  In the state of FIG. 20, when the user stops the rotation of the handle H, the coupling 126 is retracted by the urging force of the upper spring 127 to be pulled, and the retractor and withdrawal device of the air circuit breaker is in the initial state of FIG. Return. At this time, the reset actuator 124 returns to the position where the tip end portion 124 b is locked to the support member 125. Further, when the coupling 126 is retracted, the circular outer peripheral surface portion 126a of the coupling 126 is positioned within the rectangular constraining portion 129a of the lock plate 129, and the restraint is released freely. Furthermore, only the rectangular portion 122c of the pull-in and pull-out shaft 122 is fitted into the rectangular inner peripheral surface portion 126b-1 of the coupling 126 and the square portion 121b of the screw shaft 121 is released, whereby the handle H is pulled into the pull-in and pull-out shaft 122. Even if connected and rotated, the drawing and drawing shaft 122 is in an idle state, and the drawing of the air circuit breaker and the parts of the drawing device can be protected from damage due to over rotation.

  As described above, in the conventional air circuit breaker retracting and withdrawing device, the reset actuator is released and the coupling is moved to the drive transmission stop position by the spring each time the circuit breaker position, test position, and closing position are reached. As a result, the drive connection between the pull-in and pull-out shaft and the screw shaft is cut off, so that power is not transmitted even if the user keeps the handle forcibly rotated, and the components of the pull-in and pull-out device of the air circuit breaker are not It is possible to prevent damage due to overdrive.

  However, in the retractor and pull-out device of the air circuit breaker according to the prior art, when the user is switched to the drive connection state of FIG. It can operate in the closing direction, or can operate in the blocking direction when it has already been blocked, and there may be a problem that the components of the drawing-in and drawing-out device are damaged by overdrive.

  The present invention has been made to solve such a problem, and when an abnormal operation such as over-drawing or over-drawing occurs in the breaking position, the test position, and the closing position, the circuit breaker body is caused to run idle. It is an object of the present invention to provide an air circuit breaker retracting and drawing device that stops at a set position accurately and prevents breakage of the circuit breaker and the cradle.

  An air circuit breaker retracting and extracting device according to an embodiment of the present invention includes a cradle that houses a circuit breaker body, a drive shaft that is provided through first and second side plates of the cradle, and one end of the drive shaft. In the retractor and pull-out device of the air circuit breaker including the worm wheel provided in the first and second plates provided separately from the first side plate and a third plate provided separately in front of the first plate A main shaft that is rotatably provided on the first and second plates, and that has a worm gear portion that rotates the worm wheel on a part of an outer peripheral surface; and an inner side provided at a front end portion of the main shaft A clutch, a front shaft which is rotatably provided on the third plate and is coupled on the same axis as the main shaft, and a slidably provided on the front shaft It is, and an outer clutch is coupled or separated to the inner clutch.

  Here, the main shaft is formed with a lock portion protruding in a polygonal shape or an uneven shape, and the retractor and pull-out device of the air circuit breaker further includes a coupling plate coupled to or separated from the lock portion, A coupling hole in which the lock portion is fitted may be formed in the coupling plate.

  In addition, a flange supported in close contact with the third plate protrudes from a part of the front shaft, and a force in a direction for coupling the outer clutch to the inner clutch is provided between the flange and the outer clutch. A clutch spring may be provided to act.

  Further, a shaft recess may be formed in the axial direction at the rear end portion of the front shaft, and a part of the main shaft may be inserted into the shaft recess.

  Further, the rear end portion of the front shaft is formed to have a polygonal, cross-shaped or serrated cross section, and the outer clutch is polygon-shaped, cross-shaped or saw-toothed to fit the rear end portion of the front shaft. An insertion recess may be formed.

  Further, the inner clutch has an inner bent portion formed on a surface in contact with the outer clutch, and the outer clutch has an outer bent portion formed on a surface in contact with the inner clutch, and the inner clutch and the outer clutch Or coupling may occur.

  In addition, the retractor and drawer device of the air circuit breaker may further include a box-shaped padlock that is fitted to the outer peripheral surface of the front shaft and moves the coupling plate.

  Furthermore, a return spring for returning the coupling plate to its original position may be provided between the coupling plate and the first plate.

  Further, stoppers are provided on the first and second side plates, and first and second stopper locking portions are formed on one side of the drive shaft to be locked to the stoppers at the closing position and the blocking position, respectively. A cam may be provided.

  Furthermore, the first side plate may be provided with a latch for fixing the pad lock at a position moved backward.

  In the drawing-in and drawing-out device of the air circuit breaker according to the embodiment of the present invention, when an abnormal operation such as over-drawing or over-drawing occurs at a preset position such as a breaking position, a test position, and a closing position, There is an effect that the circuit breaker main body is not detached from the set position by idling.

  In addition, when the overdrive occurs, the circuit breaker pull-in and drawing-out device idles, so that the circuit breaker and the cradle are not damaged.

  Furthermore, the main shaft and the front shaft are structured such that the rotational force is transmitted by the clutch, and the driving force is generated when the user presses the pad lock at the shut-off position and the closing position to release the coupling plate. Even in a state where transmission to the main shaft is possible, the clutch slips and rotation is not transmitted, so that overdrawing and overdrawing are prevented, and there is an effect that parts are not damaged.

1 is a perspective view of a cradle to which a pull-in and pull-out device for an air circuit breaker according to an embodiment of the present invention is applied. It is a disassembled perspective view of the drawing-in and drawing-out shaft applied to the drawing-in and drawing-out device of the air circuit breaker by one Embodiment of this invention. It is a disassembled perspective view of the drawing-in and drawing-out shaft applied to the drawing-in and drawing-out device of the air circuit breaker by one Embodiment of this invention. It is a perspective view of the coupling plate applied to the drawing-in and drawing-out device of the air circuit breaker according to an embodiment of the present invention. It is a perspective view of the pad lock applied to the drawing-in and drawing-out device of the air circuit breaker according to one embodiment of the present invention. It is a perspective view which shows the interruption | blocking state of the drawing-in and drawing-out apparatus of the air circuit breaker by one Embodiment of this invention. It is a side view which shows the interruption | blocking state of the drawing-in and drawing-out apparatus of the air circuit breaker by one Embodiment of this invention. It is a perspective view which shows the idling state of a front shaft and an outer side clutch in case a driving force acts in the overdrawing direction in the drawing-in of the air circuit breaker and the interruption | blocking position of the drawing-out apparatus by one Embodiment of this invention. It is a side view which shows the state which the pad lock and the coupling plate moved back in the interruption | blocking position of the drawing-in of the air circuit breaker by one Embodiment of this invention, and the drawing-out apparatus. FIG. 8 is a side view showing the pad lock removed from FIG. 7. The idle rotation of the front shaft and the outer clutch when the driving force acts in the pull-out direction with the pad lock and the coupling plate moving rearward at the retract position of the air circuit breaker and the pull-out device according to the embodiment of the present invention. It is a side view which shows a state. It is a side view in the test position of the drawing-in and drawing-out device of the air circuit breaker according to one embodiment of the present invention. It is a side view which shows the idling state of a front shaft and an outer side clutch in case a driving force acts in the test position of the drawing-in and drawing-out device of the air circuit breaker by one Embodiment of this invention. It is a side view in the input position of the drawing-in and drawing-out device of the air circuit breaker by one Embodiment of this invention. It is a side view which shows the idling state of a front shaft and an outer clutch in case a driving force acts in the drawing-in direction of the drawing-in of the air circuit breaker and the drawing-in device according to the embodiment of the present invention. The idle rotation of the front shaft and the outer clutch when the driving force acts in the pull-in direction with the pad lock and the coupling plate moving backward at the retracted position of the retractor and pull-out device of the air circuit breaker according to the embodiment of the present invention. It is a side view which shows a state. It is an internal block diagram of the air circuit breaker by a prior art. It is a top view of the drawing-in and drawing-out device of the air circuit breaker by a prior art. It is a perspective view of a screw shaft and a coupling applied to a retractor and an extractor for an air circuit breaker according to the prior art. It is an operation state figure which shows the power transmission stop state of the drawing-in and drawing-out device of the air circuit breaker by a prior art. It is an operation state figure which shows the power transmission possible state of the drawing-in and drawing-out device of the air circuit breaker by a prior art. It is an operation state figure which shows the power transmission restraint state by the drawing-in of the air circuit breaker by a prior art, and the coupling of a drawing-out apparatus.

  Hereinafter, a description will be given in detail of a retractor and a pull-out device of an air circuit breaker according to a preferred embodiment of the present invention with reference to the accompanying drawings, which are for explaining the present invention in detail. It is not intended to limit the philosophy or scope.

  FIG. 1 is a perspective view of a cradle to which a retractor and a withdrawal device for an air circuit breaker according to an embodiment of the present invention are applied, and FIGS. 2A and 2B illustrate retracting and retracting an air circuit breaker according to an embodiment of the present invention. FIG. 3 is an exploded perspective view of a drawing and drawing shaft applied to the drawing device, FIG. 3 is a perspective view of a coupling plate applied to the drawing and drawing device, and FIG. 4 is a pad lock applied to the drawing and drawing device. FIG.

  The retractor and withdrawal device for an air circuit breaker according to an embodiment of the present invention is provided so as to penetrate the cradle 10 that houses a circuit breaker body (not shown), and the first and second side plates 11 and 12 of the cradle 10. In a pull-in / draw-out device for an air circuit breaker including a drive shaft 15 and a worm wheel 16 provided at one end of the drive shaft 15, first and second plates 20, 21 provided separately from the first side plate 11, and A worm gear portion 26 that is rotatably provided on a first plate 20 and a third plate 22 that is separated from the front of the first plate 20 and that rotates the worm wheel 16 on a part of the outer peripheral surface. The main shaft 25 is formed, the inner clutch 28 provided at the front end portion 25a of the main shaft 25, and the third plate 22 are rotatably provided. A front shaft 30 coupled to the same axis, provided so as to be sliding forward shaft 30, and an outer clutch 35 which is coupled or separated to the inner clutch 28.

  The cradle 10 may be formed in a substantially box shape whose front and upper surfaces are open. Both side portions of the cradle 10 are referred to as a first side plate 11 and a second side plate 12, respectively.

  The cradle 10 is provided with a drive shaft 15 for drawing in and drawing out the breaker body. The drive shaft 15 may be provided from the first side plate 11 to the second side plate 12.

  The worm wheel 16 provided at one end of the drive shaft 15 may be provided outside the first side plate 11. As the worm wheel 16 rotates, the drive shaft 15 coupled to the worm wheel 16 rotates.

  A plurality of cams 17 may be provided on the drive shaft 15. The cam 17 is formed with a drive groove 17a. When the cam 17 rotates together with the drive shaft 15, the circuit breaker main body installed in the drive groove 17a is drawn or pulled out.

  In order to rotate the worm wheel 16, retracting and withdrawing shafts 25, 30 are provided. Here, the pull-in and pull-out shafts 25 and 30 are configured to selectively transmit the driving force of the main shaft 25 for rotating the worm wheel 16 and a handle (not shown) to the main shaft 25. The front shaft 30 may be configured. When the main shaft 25 is coupled to the front shaft 30 and rotates together, the driving force of the handle is transmitted to the worm wheel 16, so that the circuit breaker body is retracted or pulled out. When separated, the driving force of the handle is not transmitted to the worm wheel 16, so that the circuit breaker body cannot be retracted and pulled out.

  The first and second plates 20 and 21 are provided to support the main shaft 25. The first and second plates 20 and 21 are provided perpendicular to the first side plate 11 and spaced apart from each other. A through hole is formed in each of the first and second plates 20 and 21, and the main shaft 25 is inserted and installed in the through hole. A part of the intermediate portion of the main shaft 25 may be supported by the first plate 20, and the rear end portion of the main shaft 25 may be supported by the second plate 21.

  A worm gear portion 26 is formed on a part of the main shaft 25. The worm gear portion 26 may be formed between the intermediate portion and the rear end portion of the main shaft 25, that is, between the first plate 20 and the second plate 21. Since the worm gear portion 26 meshes with the worm wheel 16, the worm wheel 16 is rotated by the rotation of the main shaft 25.

  An inner clutch 28 is provided at the front end of the main shaft 25. When the inner clutch 28 provided on the main shaft 25 and the outer clutch 35 provided on the front shaft 30 are paired and coupled to each other, the rotation of the front shaft 30 is transmitted to the main shaft 25 and separated. The rotation of the shaft 30 is not transmitted to the main shaft 25.

  The inner clutch 28 is formed with a concave and convex inner bent portion 29 on the surface in contact with the outer clutch 35. The inner bent portion 29 may be trapezoidal or wavy when viewed from the side (see FIG. 8). Thereby, even if the outer clutch 35 is engaged with the inner clutch 28, the outer clutch 35 slips off from the inner clutch 28 and idles when a large force is applied.

  The main shaft 25 is formed with a lock portion 27 that protrudes in a square shape or an uneven shape. The lock portion 27 may be formed adjacent to the rear end portion of the inner clutch 28. A coupling plate 40, which will be described later, may be coupled to or separated from the lock portion 27.

  A front end portion 25 a of the main shaft 25 is inserted and coupled to the front shaft 30. The front shaft 30 transmits the driving force from the handle to the main shaft 25 via the outer clutch 35 and the inner clutch 28. A shaft recess 33 into which a part of the front end portion 25 a of the main shaft 25 is inserted is formed at the rear end portion of the front shaft 30. The shaft recess 33 may be formed to be equal to or larger than the outer diameter of the front end portion 25a of the main shaft 25. Here, the front end portion 25a of the main shaft 25 and the shaft recess 33 of the front shaft 30 are formed to have a circular cross section and are slidably coupled to each other. As a result, when the main shaft 25 and the front shaft 30 are simply connected, the force is not transmitted to the main shaft 25 because the idle rotation occurs even if the front shaft 30 rotates.

  The front shaft 30 is provided in such a manner that a front end portion 30a is inserted into a through hole of a third plate 22 provided in the first side plate 11, and a part of the front end portion 25a of the main shaft 25 is inserted into a rear end portion. Also good.

  A flange 31 may be formed on a part of the front end portion 30 a of the front shaft 30, and the flange 31 may be provided in close contact with and supported by the third plate 22.

  A handle insertion port 32 is provided in the front end portion 30a of the front shaft 30 in the axial direction so that a user can insert a handle and manually generate a driving force. The handle insertion port 32 may be formed of a recess.

  The front shaft 30 may have a non-circle shape in the cross section of the rear end portion or the rear portion of the flange 31. For example, the front shaft 30 may have a frame cross section at the rear portion of the flange 31 in a polygonal shape, a cross shape, or a sawtooth shape. By doing so, when the outer clutch 35 is fitted to the front shaft 30, a force in the rotational direction can be received.

  The outer clutch 35 is slidably fitted to the front shaft 30. The outer clutch 35 is formed with an insertion recess 36 having a shape corresponding to the frame cross section of the front shaft 30. That is, the outer clutch 35 may be formed with an insertion recess 36 having a polygonal shape, a cross shape, or a sawtooth shape. By doing so, the rear end portion of the front shaft 30 is fitted to the outer clutch 35 so that it can advance or retreat in the axial direction.

  The outer clutch 35 is formed with a through hole 38 into which the front end portion 25a of the main shaft 25 is inserted.

  An outer bent portion 37 corresponding to the inner bent portion 29 of the inner clutch 28 is formed on the back surface portion of the outer clutch 35, that is, the portion of the outer clutch 35 that contacts the inner clutch 28. In other words, the outer bent portion 37 may be formed in a trapezoidal shape or a wave shape.

  The outer clutch 35 is fitted on the front shaft 30 and is linearly movable in the axial direction. A clutch spring 34 is provided between the outer clutch 35 and the flange 31. The clutch spring 34 provides a force that presses the outer clutch 35 toward the inner clutch 28. Thus, when no external force is applied, the outer clutch 35 is coupled to the inner clutch 28. As a result, when no external force is applied, the driving force of the handle is transmitted to the main shaft 25 via the front shaft 30, the outer clutch 35 and the inner clutch 28, so that the main shaft 25 rotates integrally with the front shaft 30. become.

  When the main shaft 25 is fixed by an external force, even if the front shaft 30 is rotated by the driving force of the handle and the outer clutch 35 is rotated in conjunction with the rotation, the outer clutch 35 slips out of the inner clutch 28 (outside Since the outer bent portion 37 of the clutch 35 and the inner bent portion 29 of the inner clutch 28 have trapezoidal or wavy inclined surfaces, they slide with each other as described above. At this time, the outer clutch 35 repeats advancing and retreating along the axis of the front shaft 30 simultaneously with rotation. That is, when the outer clutch 35 slides on the inclined surface of the contact surface of the inner clutch 28 and the projecting portion of the outer clutch 35 and the projecting portion of the inner clutch 28 come into contact with each other, the outer clutch 35 retreats and presses the clutch spring 34. When the projecting portion of the outer clutch 35 and the concave portion of the inner clutch 28 come into contact with each other, the clutch spring 34 moves forward.

  The coupling plate 40 is provided between the inner clutch 28 of the main shaft 25 and the first plate 20. The coupling plate 40 is formed with a coupling hole 41 and is movable in the axial direction of the main shaft 25. Here, the coupling hole 41 may be formed in the same shape as the outer surface of the lock portion 27. That is, the coupling hole 41 may be formed in a polygonal shape or an uneven shape.

  Sliding protrusions 42 are formed on both side surfaces of the coupling plate 40 so as to be slidably provided between the first side plate 11 and the cover plate 13. Since the sliding protrusion 42 of the coupling plate 40 is slidably fitted in the sliding hole (not shown) of the first side plate 11 and the sliding hole 13a of the cover plate 13, the coupling plate 40 is attached to the main shaft 25. It can move forward and backward in the axial direction. Since the coupling plate 40 is provided in close contact between the first side plate 11 and the cover plate 13, it does not move in the rotational direction of the main shaft 25.

  A part of the coupling plate 40 may be formed with an insertion hole 43 in which a part of a pad lock 50 described later is fitted and fixed.

  A return spring 45 is provided between the coupling plate 40 and the first plate 20. The return spring 45 presses the coupling plate 40 toward the inner clutch 28 because the first plate 20 is fixed. Therefore, when no other external force acts, the lock portion 27 is fitted in the coupling hole 41 and the coupling plate 40 is maintained in close contact with the inner clutch 28. When the coupling plate 40 is coupled to the lock portion 27, the main shaft 25 is restrained by the coupling plate 40 and does not rotate.

  When the coupling plate 40 is released from the lock portion 27 while compressing the return spring 45 by an external force, the main shaft 25 is released from the restraint by the coupling plate 40 and freely rotates.

  A padlock 50 is provided on the front shaft 30. The pad lock 50 may be formed in a box shape. A shaft insertion hole 51 is formed through the pad lock 50 in the longitudinal direction, and the front shaft 30 is fitted therein. On the front surface of the padlock 50, a pressing protrusion 52 is provided so as to be pressed by the user. When an external force does not act, that is, when the user does not press the pressing protrusion 52, the pad lock 50 is in a state where the back surface is in contact with the coupling plate 40. At this time, the coupling plate 40 is connected to the lock portion 27. When the user presses the pressing protrusion 52, the pad lock 50 moves rearward to press the coupling plate 40, and the coupling plate 40 is released from the lock portion 27.

  A latch 55 is provided to fix the pad lock 50 in a state where the pad lock 50 is moved rearward (that is, in a state where the coupling plate 40 is detached from the lock portion 27). The latch 55 is rotatably provided on a part of the first side plate 11 and receives a clockwise force by a spring (not shown). A latch step 53 is formed on the upper portion of the padlock 50. With the padlock 50 moving rearward, the latch 55 rotates clockwise and is locked to the latch step 53, and the padlock 50 is fixed. . When the latch 55 rotates counterclockwise by an external force and is disengaged from the latch stage 53, the padlock 50 returns to the front together with the coupling plate 40 by the restoring force of the return spring 45. Here, the latch 55 may be adjusted so as to move at positions preset by the indicator 60 (for example, a blocking position, a test position, and a closing position). A projection 61 is formed on the indicator 60, and a counterclockwise force can be applied by pressing the left end of the latch 55 at the blocking position, the test position, and the closing position.

  The cam 17 is provided to transmit the drawing and drawing movement force to the circuit breaker body. The cams 17 are provided as a pair, are provided on a part of the drive shaft 15 so as to be adjacent to the inside of the first side plate 11 and the second side plate 12, respectively, and rotate together with the drive shaft 15. The cam 17 is formed with a drive groove 17a to transmit a driving force so that the circuit breaker body is pulled or pulled out.

  A stopper 18 is provided to restrain the movement of the cam 17. The stopper 18 protrudes from the first side plate 11 and the second side plate 12. The cam 17 is formed with a first stopper locking portion 17b and a second stopper locking portion 17c so as to be locked and fixed to the stopper 18 at the closing position or the blocking position. At the breaking position of the circuit breaker, the first stopper latching portion 17b of the cam 17 is latched by the stopper 18 and the cam 17 and the drive shaft 15 are prevented from rotating counterclockwise, whereby the worm wheel 16 and the main shaft 25 are blocked. The movement of is also restrained. Therefore, overdrawing of the circuit breaker body is prevented. Further, at the closing position of the circuit breaker, the second stopper locking portion 17c of the cam 17 is locked to the stopper 18 and the cam 17 and the drive shaft 15 are prevented from rotating in the clockwise direction, thereby the worm wheel 16 and the main shaft. The movement of 25 is also restrained. Therefore, overdrawing of the breaker body is prevented.

  Hereinafter, the operation of the drawing-in and drawing-out device of the air circuit breaker according to one embodiment of the present invention will be described.

  FIG. 5A is a perspective view showing a cutoff state of the retractor and the drawing device of the air circuit breaker according to the embodiment of the present invention, and FIG. 5B is a side view showing a cutoff state of the drawing and the drawing device.

  When the handle is driven in the overdraw direction in the shut-off state as shown in FIGS. 5A and 5B, the main shaft 25 is constrained from rotating because the lock portion 27 is coupled to the coupling plate 40, so the driving force of the front shaft 30 is Although the outer clutch 35 is rotated, the outer clutch 35 is not transmitted to the main shaft 25 because the outer clutch 35 slips out of the inner clutch 28. That is, the front shaft 30 and the outer clutch 35 idle. Thereby, overdrawing of the circuit breaker body is prevented. Further, since the cam 17 is restrained by the stopper 18 and is prevented from rotating in the overdrawing direction, the circuit breaker body is not overdrawn. FIG. 6 is a perspective view showing an idling state of the front shaft and the outer clutch when a driving force acts in the overdrawing direction at the retracted position of the air circuit breaker and the withdrawal device according to the embodiment of the present invention. A state in which the outer clutch 35 is engaged with the inner clutch 28, cannot transmit the rotational force and slips and idles is shown. FIG. 6 shows a state in which the pad lock 50 is removed to help understanding.

  When the user presses the pressing protrusion 52 of the padlock 50 and moves the padlock 50 rearward (to the right in FIG. 5B) in the interrupted state (FIGS. 5A and 5B), The coupling plate 40 in contact with the padlock 50 also moves backward. When the pad lock 50 moves rearward, the latch 55 rotates clockwise and is locked to the latch stage 53, so that the pad lock 50 is fixed. 7 and 8 show a state in which the pad lock 50 and the coupling plate 40 have moved rearward. FIG. 8 shows the padlock removed from FIG. Since the coupling plate 40 is disengaged from the lock portion 27, the main shaft 25 is allowed to rotate, and the driving force of the front shaft 30 is transmitted to the main shaft 25.

  Therefore, when the user inserts the handle into the handle insertion port 32 and rotates the front shaft 30, the breaker body can be retracted. At this time, when the user rotates the handle in the direction in which the breaker body is pulled, the driving force is transmitted to the worm wheel 16 via the front shaft 30 and the main shaft 25, whereby the driving shaft 15 rotates and cams. The main body of the circuit breaker locked to 17 is drawn.

  On the other hand, when the user rotates the handle in the direction of pulling out the breaker body, the driving force tries to rotate the front shaft 30 and the main shaft 25, but the stopper 18 has the first stopper locking portion 17 b of the cam 17. Is locked and rotation of the worm wheel 16 is prevented, so that rotation of the main shaft 25 with which the worm gear portion 26 is engaged is not allowed. Even if the user applies a force to cause overdraw, the outer clutch 35 slips out of the inner clutch 28 as shown in FIG. Will not be transmitted.

  When the padlock 50 moves rearward and the rotation of the front shaft 30 is transmitted to the main shaft 25 in the state shown in FIG. It is transmitted to the worm wheel 16 through the shaft 30 and the main shaft 25, and the drive shaft 15 and the cam 17 rotate to move the breaker body to the test position. At this time, when the indicator 60 rotates and the protrusion 61 presses the left end of the latch 55, the latch 55 is disengaged from the latch stage 53 of the pad lock 50, and the pad lock 50 and the coupling plate 40 are connected to the return spring 45. Return to the original position (left side of the figure) by restoring force. FIG. 10 shows a state in which the circuit breaker body is in the test position in this way. The worm wheel 16 and the cam 17 are rotated clockwise by a predetermined angle, and the pad lock 50 and the coupling plate 40 are returned to their original positions. Even if the handle is rotated in this state, since the main shaft 25 is fixed with the lock portion 27 coupled to the coupling plate 40, the driving force of the front shaft 30 causes the outer clutch 35 to slip from the inner clutch 28. As a result, it is not transmitted to the main shaft 25. FIG. 11 shows a state where the overdrive is performed at the test position and the front shaft 30 and the outer clutch 35 are idling.

  In the state shown in FIG. 10, when the user presses the pressing protrusion 52 of the pad lock 50 to move the pad lock 50 and the coupling plate 40 rearward and fix them, the driving force of the handle is changed from the front shaft 30 to the main shaft 25. Will be transmitted to. When the user rotates the handle in the direction in which the breaker body is pulled, the driving force of the handle is transmitted to the worm wheel 16 via the front shaft 30 and the main shaft 25, and the drive shaft 15 and the cam 17 rotate to rotate the breaker. Move the body to the loading position. At this time, when the indicator 60 rotates and the protrusion 61 presses the left end of the latch 55, the latch 55 is disengaged from the latch stage 53 of the pad lock 50, and the pad lock 50 and the coupling plate 40 are connected to the return spring 45. Return to the original position (left side of the figure) by restoring force. FIG. 12 shows a state in which the breaker body is in the closing position. The worm wheel 16 and the cam 17 are further rotated in the clockwise direction so that the stopper 18 comes into contact with the second stopper locking portion 17c of the cam 17, and the pad lock 50 and the coupling plate 40 are returned to their original positions. It is shown. Even if the handle is rotated in this state, since the main shaft 25 is fixed with the lock portion 27 coupled to the coupling plate 40, the driving force of the front shaft 30 causes the outer clutch 35 to slip from the inner clutch 28. As a result, it is not transmitted to the main shaft 25. Further, since the cam 17 is also locked by the stopper 18 and cannot be rotated, the circuit breaker body is prevented from being excessively retracted. FIG. 13 shows a state where the overdrive is performed at the closing position and the front shaft 30 and the outer clutch 35 are idling.

  When the user presses the pressing protrusion 52 of the pad lock 50 and moves the pad lock 50 and the coupling plate 40 rearward in the inserted state of FIG. When the handle is rotated in the over-retraction direction, the cam 17 is prevented from rotating by the second stopper engagement portion 17c being engaged with the stopper 18, so that the over-retraction of the circuit breaker body is prevented, and the inner clutch 28 is The clutch 35 idles without being able to transmit the rotational force. Such an idling state is shown in FIG.

  In the drawing-in and drawing-out device of the air circuit breaker according to the embodiment of the present invention, when an abnormal operation such as over-drawing or over-drawing occurs at a preset position such as a breaking position, a test position, and a closing position, There is an effect that the circuit breaker main body is not detached from the set position by idling.

  In addition, when the overdrive occurs, the circuit breaker pull-in and drawing-out device idles, so that the circuit breaker and the cradle are not damaged.

  Furthermore, the main shaft and the front shaft are structured such that the rotational force is transmitted by the clutch, and the driving force is generated when the user presses the pad lock at the shut-off position and the closing position to release the coupling plate. Even in a state where transmission to the main shaft is possible, the clutch slips and rotation is not transmitted, so that overdrawing and overdrawing are prevented, and there is an effect that parts are not damaged.

  The embodiments described above implement the present invention, and various modifications and variations can be made by those having ordinary knowledge in the technical field to which the present invention pertains without departing from the basic characteristics of the present invention. It will be possible. That is, the above-described embodiment is merely for explaining the technical idea of the present invention, and the scope of the technical idea of the present invention is not limited by the above-described embodiment. The scope of the right of the present invention should be determined by the appended claims, and all technical ideas within the equivalent scope should be construed as being included in the scope of the right of the present invention.

DESCRIPTION OF SYMBOLS 10 Cradle 11 1st side plate 12 2nd side plate 13 Cover plate 13a Sliding hole 15 Drive shaft 16 Worm wheel 17 Cam 17a Drive groove part 17b First stopper latching part 17c Second stopper latching part 18 Stopper 20 First plate 21 First 2 plate 22 3rd plate 25 main shaft 25a front end portion 26 worm gear portion 27 lock portion 28 inner clutch 29 inner bent portion 30 front shaft 30a front end portion 31 flange 32 handle insertion port 33 shaft recess portion 34 clutch spring 35 outer clutch 36 insertion recess portion 37 Outer bent portion 38 Through hole 40 Coupling plate 41 Coupling hole 42 Sliding projection 43 Insertion hole 45 Return spring 50 Pad lock 51 Shaft insertion hole 52 Press projection 53 Latch step 55 60 indicator 61 protrusion

Claims (9)

In an air circuit breaker pull-in and pull-out device including a cradle that houses a breaker body, a drive shaft that is provided through the first and second side plates of the cradle, and a worm wheel that is provided at one end of the drive shaft.
A first plate, a second plate provided separately from the first side plate, and a third plate provided separately from the front of the first plate;
A main shaft that is rotatably provided on the first and second plates, has a lock portion that protrudes in a polygonal shape or an uneven shape, and has a worm gear portion that rotates the worm wheel on a part of the outer peripheral surface. When,
An inner clutch provided at the front end of the main shaft;
A front shaft that is pivotally provided on the third plate and coupled on the same axis as the main shaft;
An outer clutch slidably provided on the front shaft and coupled or separated from the inner clutch;
Coupling plate coupled or separated to said locking portion, only including,
A pull-in and pull-out device for an air circuit breaker , wherein a return spring is provided between the coupling plate and the first plate to act in a direction to couple the coupling plate to the lock portion . Before SL coupling plate wherein the locking portion is fitted coupling hole is formed, draw in-out apparatus for the air circuit breaker according to claim 1. A flange supported in close contact with the third plate protrudes from a part of the front shaft,
3. The retractor and retractor for an air circuit breaker according to claim 1, wherein a clutch spring is provided between the flange and the outer clutch so that a force in a direction of coupling the outer clutch to the inner clutch acts. . A shaft recess is formed in the axial direction at the rear end of the front shaft,
The drawing-in and drawing-out device of the air circuit breaker according to any one of claims 1 to 3, wherein a part of the main shaft is inserted into the shaft recess. The rear end portion of the front shaft is formed to have a polygonal shape, a cross shape, or a sawtooth cross section,
The air circuit breaker retractor according to any one of claims 1 to 4, wherein the outer clutch is formed with a polygonal, cross-shaped or serrated insertion recess into which a rear end portion of the front shaft is fitted. And drawer device.   The inner clutch has an inner bent portion formed on a surface in contact with the outer clutch, and the outer clutch has an outer bent portion formed on a surface in contact with the inner clutch, and the inner clutch and the outer clutch are coupled to each other. Or the drawing-in and drawing-out device of the air circuit breaker according to any one of claims 1 to 5, wherein slipping occurs.   The air circuit breaker retracting and extracting device according to claim 2, further comprising a box-shaped padlock that is fitted to an outer peripheral surface of the front shaft and moves the coupling plate. A stopper protrudes from the first and second side plates,
The first is engaged with the stopper, respectively on position and the blocking position on one side of the drive shaft, the second cam stopper engaging portion is formed is provided, any one of claims 1-7 The drawing-in and drawing-out device of the air circuit breaker described in 1. The pull-in and pull-out device of the air circuit breaker according to claim 7 , wherein the first side plate is provided with a latch for fixing the pad lock at a position moved rearward.